Hydraulic Device and Method for Locating and Sealing Holes or Cracks in Oil Well Production Tubing

ABSTRACT

The invention relates to a hydraulic device for in situ hermetic sealing of holes, cracks or leaks from joints that occur in underground production tubing used for the extraction of oil, gas or other fluids. In particular, the invention relates to a device comprising an assembly including four sections comprising various securing and anchoring means, and to the method for moving the device in order to detect and locate the site of the leak and to position the device inside the fluid production tubing, such that it remains fixed in place and hermetically seals the damaged section of the production tubing, allowing normal production flow to be resumed.

FIELD AND PURPOSE OF THE INVENTION

The present invention relates to production tubing at oil wells, and to a device and a method for in situ sealing of holes or cracks caused as a result of corrosion and other factors on the walls of the tubes intended for oil extraction, at any section thereof. Specifically, it relates to a new device that works by hermetically sealing the hole or crack through which the leak occurs. Once the leak is detected from the surface by means of hydraulic displacement of the device in a controlled manner up to the leak site, the device becomes attached to the hole or crack in such a way that, once settled, attached and sealed, it allows to immediately resume the inner flow in the oil production process, thus avoiding the need to stop production for a long time, until the tubing is removed and the hole is sealed on the surface.

STATE OF THE ART BACKGROUND

Oil production in a well is carried out through production tubes that are installed from the surface to the bottom, at the level where the production field is located. Such tubes, whose diameter is smaller than that of the well casing tubes, are made of steel and generally feature high resistance to the corrosion caused by fluids (water, oil and gas) flowing from the well towards the surface. However, the tubing's resistance to corrosion has limits which, once exceeded, may lead to severe alterations, such as holes or cracks which, though localized, seriously affect production continuity.

In the case of oil and other fluids, the existence of a hole or crack is quickly determined after observing a pressure drop in the extraction fluid. Thus on noticing that there is a leak in the production tubing, the cause must be repaired as soon as possible, particularly for cost reasons (due to product losses) and because, if left unattended, it may lead to a worsening of its causes, to the point where the extraction must be stopped for a long time in order to repair it, which results in a substantial increase in production costs, not only from the paralysis in the crude oil extraction, but also from the costs associated with the entire piping assembly and control accessories, fluid extraction pumps (where applicable), sleeves and other elements which are part of the piping assembly and the internal completion of the extraction tubing at the oil well, as well as its subsequent replacement to resume the pumping activity.

In oil fields there are a large number of wells that are closed due to broken pipes or the formation of a hole or crack, thus causing a loss of production. The time when the broken tubing is to be changed depends on the availability of reconditioning drills; therefore, the waiting time for well reconditioning may be weeks or months.

In the state of the art, some procedures were developed with the intention to solve this problem, such as those described in the following patents:

Patent EP 2304306 A1, “Method for in-situ repair of a hole in pipe in pipe tubular”, of 31st Mar. 2009. This patent presents a method for the in situ repair of a hole in tubular pipes. The method comprises the following steps: Introduction of a hole sealing device for tubular pipes, identification of a hole in the tubing, and injection of a sealing agent in the hole through a hole sealing device. Consequently, any holes in the pipes of tubular piping may be repaired without the costs involved in the extraction of interior pipes from the outside. Additionally, a suitable device for the method is supplied.

U.S. Pat. No. 5,785,120, TUBULAR PATCH. 28 Jul. 1998. This patent presents: A tubular patching system for patching operations which, in one aspect, is useful as a tubular patching system “through the tubing”, with a body and a series of selectively expandable members that, after going through a tubular pipe with a first diameter, they expand into a tubular pipe with a second diameter which is greater than the first, and may be then operated to expand a coating patch intended to seal a leak in the tubular pipe with the second diameter. Said system may be used in a tubular pipe arranged inside a well or in a tubular pipe in the earth's surface.

The methods proposed by the above cited patents are different from the method proposed by the present invention, since the latter does not include the application of any sealing agents or patches to fill the hole. Instead, a hydraulic device is used in order to detect a hole or crack and to insulate it; such a device is installed at the place where the hole or crack is located, and the production is resumed immediately thereafter.

BRIEF DESCRIPTION OF THE INVENTION

The present invention relates to a hydraulic device and a method to determine the location of the leak site in the underground tubing, whether caused by a hole or crack, or by a leak in a threaded joint, in the tubing where oil or a similar liquid flows, which is located underground. The innovative hydraulic device and the method allow location and sealing of any holes or cracks in the production tubing of oil wells. The device comprises an upper section, a lower section, an extension section, a hydraulic positioner for location of leaks, as well as an anchoring means to attach the device at the level of the hole or crack.

This device is hydraulically moved from the surface and is driven through the inside of the production tubes by means of a fluid at a pressure of 344.74 KPa (50 psi). Whenever a hole or crack is detected, the device stops. At this moment, the technician who is monitoring the operation on the surface proceeds to increase, in several stages, the hydraulic pressure of the fluid so that the equipment is anchored at that location and creates a hermetic seal between the body of the hydraulic device and the hole or crack that is detected in the production tubing, thus allowing for the well fluid to resume its normal flow through the internal tubes that are a part of the hydraulic device, once the hole or seal has been sealed by implementing such device.

Consequently, the invention swiftly and safely solves the problem of a decreased outlet flow and the pressure drop caused by a leak of the fluid being extracted, particularly, in the oil production tubing which, as previously noted, leads to major operation losses due to the high costs required by the current extraction practices.

The purpose of the present invention is that, whenever a hole or crack appears in the production tubing of an oil well or in a threaded joint at any depth, there is no need to perform a reconditioning of the well, which would entail having a tower available to recover the entire production drilling train and to detect the location of the damaged tube or accessory for their replacement. Such activities would cause a loss of at least 7 days of production in the well, and the cost of maintenance or replacement of the accessories and the well pump. This situation is solved in a simple and economical way by using the present hydraulic device and method to locate and seal holes or cracks in production tubing at oil wells, thus allowing for the well to resume its normal operations within approximately 6 hours.

The device and method described in the present specification must be preferably used in wells equipped with oil lifting means with submersible electric pumps, hydraulic pumping, or natural flow production. The device is between 2.00 and 3.00 m long, and has a diameter of between 75 mm and 115 mm.

BRIEF DESCRIPTION OF FIGURES

FIG. 1 represents a schematic view of the Typical Mechanical Completion of an Oil Well with Hydraulic, Electric and/or Natural Flow, where the following is specified: the well's header with its respective plug [FIG. 1(01)]; a central valve to introduce tools or devices to the bottom of the well [FIG. 1(02)] through the production tubing, the production tubing [FIG. 1(03)] which allows for the flow and high pressure injection of driving fluid towards the underground pump located in the circulation sleeve [FIG. 1(04)], which may be a jet hydraulic pump or a submersible electric pump, or neither of the above in the case of fluid production by Natural Flow; the annular space [FIG. 1(05)]; the coating tube [FIG. 1(06)]; the gasket [FIG. 1(07)], installed at the bottom of the well, which permits to insulate the field [FIG. 1(08)] from the annular space [FIG. 1(05)]. Additionally, the completion includes a settling nipple [FIG. 1(09)], which houses the hydraulic closing valve to perform leak tests on the production tubing [FIG. 1(03)]; and an insulating plug [FIG. 1(11)]; to separate the deeper fields.

FIG. 2 represents a cross section view of the hydraulic device assembled as per the present invention, comprising four sections: upper section, extension section, central section, and lower section.

The Upper Section comprises: the Fishing Neck [FIG. 2(12)], which is used for the recovery of the Hydraulic Device via wire line; 1 Upper Cylinder [FIG. 2(13A)], where the upper displacement means are coupled, comprising 2 Spacers [FIG. 2(14A)], 2 Retainer Rubbers [FIG. 2(15A)], 2 Rubber Retainers [FIG. 2(16A)], and an Adjuster Nut [FIG. 2(17A)] to adjust the rubber retainers [FIG. 2(15A)]. Finally, 1 Reduction [FIG. 2(18A)].

The Extension Section comprises: 1 Upper Piston [FIG. 2(19B)], to which the upper sealing means is coupled, comprising 3 Expansion Joints [FIG. 2(20B)] attached to the upper end of the Extension Tube [FIG. 2(24B)] by an Upper Joint Retainer [FIG. 2(21B)], which is in turn attached to the Extension Tube by 2 Cutting Set Screws [FIG. 2(22B)]. At the lower end of the Upper Piston [FIG. 2(19B)], there are elements for the temporary obstruction of the internal flow communication, comprising 1 Disc Retainer [FIG. 2(23B)] and a Rupture Disc [FIG. 2(34B)].

The Central Section comprises: a Lower Adapter [FIG. 2(25C)] for start-up, whose role is to connect the Extension Tube [FIG. 2(24B)] with the Central Cylinder [FIG. 2(26C)], where the lower displacement means is coupled, comprising 2 Spacers [FIG. 2(14C)], 2 Retainer Rubbers [FIG. 2(15C)], 1 Rubber Retainer [FIG. 2(16C)]. This allows to detect the hole or crack in the production tubing, thanks to the lower Retainer Rubber [FIG. 2(15C)] placed in an upside down position relative to the upper retainer rubber.

The Lower Section comprises: the Lower Piston Casing [FIG. 2(27D)], which also acts as a point of convergence between the Central Cylinder [FIG. 2(26C)] and the Lower Cylinder [FIG. 2(29D)] comprises two flow holes [FIG. 2(35D)]; within the casing, the Lower Piston [FIG. 2(28D)] slides and activates the lower sealing means, comprising 3 Expansion Joints [FIG. 2(20D and a Lower Joint Retainer [FIG. 2(30D)], which sets the position of the expansion joints. At the lower end of the Lower Piston [FIG. 2(28D)], the Sliding Cone is connected [FIG. 2(31D)], which in turn activates the anchor means, comprising a Cage [FIG. 2(33D)], 2 Wedges [FIG. 2(32D)], a Disc Retainer [FIG. 2(23D)], and a Rupture Disc [FIG. 2(34D)].

FIG. 3 shows a cross section view of the Hydraulic Device [FIG. 2] moving through the interior of the Production Tubing [FIG. 1(03)]. The upper and lower Retainer Rubbers [FIGS. 2(15A) and 2(15C)], are already expanded, and the fluid leaking through the hole or crack [FIG. 3(10)] when the Hydraulic Device [FIG. 2] continues to move towards the hole or crack through the interior of the production tubing [FIG. 1(03)].

FIG. 4 shows a cross section view of the hydraulic device (FIG. 2) after being settled, anchored and sealing the hole or crack, once the hole or crack has been detected [FIG. 3(10)]. The Retainer Rubber is upside down [FIG. 4(15C)], blocking the flow through the hole or crack [FIG. 4(24B)]; the 2 upper Cutting Set Screws [FIG. 4(22B)], now cut; the Upper Piston [FIG. 4(19B)], displaced inside the Extension Tube [FIG. 4(24B)]; the 3 upper Expansion Joints [FIG. 4(20B)], now expanded; the Rupture Disc [FIG. 4(34B)], now broken; the fluid flowing through the Extension Tube [FIG. 4(24B)], Central Cylinder [FIG. 4(26C)], Lower Cylinder [FIG. 4(29D)], and the 2 flow holes [FIG. 4(35D)]; the Lower Piston Housing [FIG. 4(24B)] shows the 2 lower Cutting Set Screws [FIG. 4(22D)], already cut, the Lower Piston [FIG. 4(28D)], displaced downwards, the 3 lower Expansion Joints [FIG. 4(20D)], already expanded, the lower 2 Wedges [FIG. 4(32D)], anchored to the production tubing [FIG. 4(32D)] by the Sliding Cone [FIG. 4(31D)], which is displaced downwards, and the lower Rupture Disc [FIG. 4(34D)], already broken.

FIG. 5 shows a cross section view of the flow path inside the hydraulic device, once the hole or crack has been detected, and the inverted internal path of the flow going up the lower cylinder [FIG. 5(29D)], the central cylinder [FIG. 5(26C)], the Extension Tube [FIG. 5(24B)], the upper cylinder [FIG. 5(13A)], and going out through the fishing neck [FIG. 5(12)], to continue to flow through the production tubing [FIG. 5(03), once the hole or crack has been filled.

FIG. 6 shows a cross section view of the anchor means in the hydraulic device [FIG. 2], now activated. It shows the hole or crack [FIG. 6(10)] in the production tubing [FIG. 6(03)], the location of the 2 lower Wedges [FIG. 6(32D)] and the Sliding Cone [FIG. 6(31D)].

DETAILED DESCRIPTION OF THE INVENTION

To apply the hydraulic device and the method to locate and seal holes or cracks in production tubing at oil wells, the following steps will be taken:

First Step: Before a sealing method is carried out, the technical traits to be met by the completion and the well to be intervened must be determined, which must comply with the following specifications:

-   -   a) The oil lifting type, preferably by jet hydraulic pumping         (JHP), natural flow (NF), or submersible electric pumping (SEP)         (FIG. 1);     -   b) the diameter of the production tubing [FIG. 1(03)] installed,         which must be between 75 mm and 115 mm;     -   c) having a settling nipple [FIG. 1(09)] and a flow sleeve in         place [FIG. 1(04)] at the bottom of the production tubing.     -   d) having the following data records in connection with the well         and the completion: production flows, parameters of produced         fluids, well bottom pressures, and operating pressures for         artificial type lifting.

Second Step: Perform leak tests on the tubing

Once the well and completion information is available, a leak test will be performed on the production tubing [FIG. 1(03)] and, for this purpose, a valve must be installed at the bottom of the well, on the settling nipple [FIG. 1(09)], or in the circulation sleeve [FIG. 1(04)], such installation being usual and known in the state of the art. Once the valve is installed at the bottom of the well, the production tubing is then pressurized by pumping a fluid from the surface, at an increasing pressure within a range of 689.48 KPa (100 psi) to 27,939.03 KPa (4000 psi); if there comes a time when the pressure of the pumped fluid no longer increases, then the production tubing is hermetic; otherwise, if the pressure decreases, this would confirm the presence of a fluid leak through a hole or crack [FIG. 3(10)] in any section of the production tubing [FIG. 1(03)] towards the annular space [FIG. 1(05)]. Then, note the information relative to the flow of the fluid that runs through the annular space FIG. (1. 05), which corresponds to the flow of the fluid running through the hole or crack [FIG. 3(10)], using, for this purpose, a flow meter on the surface. The flow information is important in order to determine the characteristics of the hole or crack on the production tubing.

Third Step: Hermetic sealing method

Once the above steps have been carried out, and after confirming the existence of a hole or crack on the production tubing [FIG. 1(03)], the following method is then conducted, by using the innovative hydraulic device, as described in [FIG. 2], which is introduced and coupled to the production tubing until it becomes hermetically sealed:

The hydraulic device [FIG. 2] is hydraulically displaced from the surface at a pressure of 344.74 KPa (50 psi) through the production tubing interior, which is filled with the fluid used in the leak test previously described; when the device stops and the pressure increases, the location of the hole or crack [FIG. 4 (10)] may be detected, and this event occurs because the device can no longer move forward, as it has reached the level of the fluid column caught between the bottom valve and the level at which the hole or crack is situated; at this moment, the technician who is monitoring the operation on the surface proceeds to increase the hydraulic pressure so the device can be attached in that location [FIG. 5] and it creates a hermetic sealing between the body of the hydraulic device and the production tubing through the upper expansion joints [FIG. 4(20B)] and the lower expansion joints [FIG. 4(20D)], filling the hole or crack [FIG. 4(10)] that was detected in the production tubing [FIG. 4(03)] and thus allowing for the free circulation of fluids, with no leakage, between the well and the surface or vice versa, through the hydraulic device.

In order to run the above method, the following steps are taken:

-   -   I. DISPLACEMENT OF THE HYDRAULIC DEVICE         -   1. The pumped fluid comes in through the Fishing Neck [FIG.             2(12)], it goes through the upper cylinder [FIG. 2(13A)],             until it gets pressurized in the Rupture Disc [FIG. 3(34B)],             thus forcing the Hydraulic Device to move downwards.         -   2. At the same time, the fluid outside the Hydraulic Device             [FIG. 2] causes the expansion of the Retainer Rubbers [FIG.             3(15A)], which controls the downward movement of the             hydraulic device.         -   3. Consequently, the existing fluid at the production tubes             is progressively pushed by the hydraulic device [FIG. 2], as             it is pressed downwards and forced to exit through the hole             or crack [FIG. 3(10)] on the production tubing [FIG. 3(03)],             until the detection means or the Retainer Rubber that is now             inverted downwards [FIG. 4(15C)] surpasses the hole or             crack, thus bringing the leak to an end.     -   II. LOCATION OF HOLE OR CRACK AND SETTLING OF UPPER SECTION         -   1. At the moment when the hole or crack [FIG. 4(10)] is             blocked, the pressure measured on the surface is increased             until it reaches 8273.76 KPa (1200 psi), which causes the             breakage of the Cutting Set Screws [FIG. 4(22B)], thus             releasing the Upper Piston [FIG. 4(19B)], which begins to go             down through the inside of the Extension Tube [FIG. 4(24B)]             at the Extension Section, and then goes into the interior             diameter of the upper Expansion Joints [FIG. 4(20B)] and             presses them against the interior walls of the production             tube [FIG. 4(03), leaving the Upper Section [FIG. 4] of the             Hydraulic Device hermetically sealed and settled [FIG. 2].     -   III. SETTLING OF LOWER SECTION         -   1. To continue with the settling of the Lower Section,             pressure is increased up to 15,168.56 KPa (2200 psi), which             causes the upper Rupture Disc to break [FIG. 4(34B)] at the             Upper Section, causing the fluid that is pumped from the             surface to flow downwards through the Extension Tube [FIG.             4(24B)] at the Extension Section, in the Central Cylinder             [FIG. 4(24B)] at the Central Section, and in the Lower             Cylinder [FIG. 4(29D)] at the Lower Section, until it             reaches the lower Rupture Disc [FIG. 4(34D)]. Then, pressure             is reduced to its prior lower value.         -   2. The pressure of the fluid is increased in order to push             it through the flow holes [FIG. 4(35D)] in the Lower             Cylinder [FIG. 4(29D)], until pressure is exerted on the             Lower Piston [FIG. 4(27D)] and a pressure of 9,652.72 KPa             (1400 psi) is reached, which causes the 2 lower Cutting Set             Screws to break [FIG. 4(22D)], thus displacing the Lower             Piston [FIG. 4(24B)] downwards, until it goes into the             interior diameter of the lower Expansion Joints [FIG.             4(20D)] and presses them against the interior walls of the             production tube [FIG. 4(03), thus leaving the Lower Section             [FIG. 4] of the Hydraulic Device hermetically sealed and             settled.     -   IV. ANCHORING OF SLIDING CONE         -   1. The last cited action causes the anchoring of the Sliding             Cone [FIG. 4(31D)], which is threaded to the Lower Piston             [FIG. 4(28D)], in the Wedges [FIG. 4(32D)] through the             inside of the Cage [FIG. 4(33D)], thus leaving the Lower             Section of the Hydraulic Device hermetically sealed and             anchored [FIG. 2] against the walls of the Production Tubing             [FIG. 4(03)].     -   V. HERMETIC SEALING COMPLETION         -   1. Pumping pressure is continuously increased up to 17237             KPa (2500 psi) in order to check the settling of the             Hydraulic Device [FIG. 2]. Once this is verified, the lower             Rupture Disc [FIG. 4(34D)] breaks, thus establishing             communication between the lower [FIG. 5(29D)], central [FIG.             5(26C)] and upper cylinders [FIG. 5(13A)], so that the             fluids may flow [FIG. 1(08)] normally through the interior             of the Hydraulic Device [FIG. 2] and the production tubing,             in any direction. 

1. A hydraulic device for in situ sealing of cracks and holes in the production tubing of oil wells, located underground, said device being assembled along 4 sections with a total length of 2.00 m to 3.00 m and a diameter of 70 to 80 mm, and it comprises: a) an upper section, comprising: 1 upper cylinder, and upper displacement means; b) an extension section, comprising: an upper piston, an upper sealing means located on the upper segment of the upper piston, 1 extension tube whose upper part holds the upper piston by means of 2 set screws, and whose lower part is coupled with a central section, and 1 lower adapter, to connect the lower part of the extension section to the central section; c) the central section, comprising: a central cylinder, lower displacement means, and, wherein the lower part of the central section is connected to a lower piston housing; and, d) a lower, comprising: the lower piston housing, whose lower part contains 2 set screws, 1 lower cylinder, 1 lower piston, a lower sealing means, 1 sliding cone, and anchoring means, comprising 1 cage, 2 wedges.
 2. The hydraulic device as claimed in claim 1, wherein the upper cylinder is connected by its upper part to a Fishing Neck by means of a threaded joint and, by its lower part, to the extension section through a reduction.
 3. The hydraulic device as claimed in claim 1, wherein the upper sealing means of the upper section comprises: 2 spacers, 2 retainer rubbers, 2 rubber retainers and 1 adjuster nut to adjust the retainer rubbers.
 4. The hydraulic device as claimed in claim 3, wherein the retainer rubbers are shaped like a truncated cone, with the larger diameter placed upwards.
 5. The hydraulic device as claimed in claim 1, wherein the upper piston at the extension section has an external diameter that gradually varies from top to bottom, featuring the larger diameter at the upper part, with a flange that acts as a stopper; next, there is a second segment where the piston diameter is reduced by a length similar to that of expansion joints, and the remaining segment, with an even smaller diameter, is introduced into the extension tube after going through the upper sealing means; and the lower segment of the piston is covered by a rupture disc, which is supported by a disc retainer.
 6. The hydraulic device as claimed in claim 1, wherein the upper sealing means are located on the piston segment with the smaller diameter, and they comprise: 3 expansion joints attached to the upper end of the extension tube by an upper joint retainer.
 7. The hydraulic device as claimed in claim 1, characterized by the fact that the extension tube has cutting set screws on its upper part, which hold the upper piston, and it features the lower adapter on its lower part, allowing it to couple with the central section.
 8. The hydraulic device as claimed in claim 1, wherein the lower displacement means situated in the central section comprise 2 spacers, 2 retainer rubbers, and 1 rubber retainer.
 9. The hydraulic device as claimed in claim 1, where the retainer rubbers are shaped like a truncated cone, with the larger diameter placed in opposite directions, upwards and downwards.
 10. The hydraulic device as claimed in claim 1, wherein the lower cylinder of the lower section has two flow holes on its upper part, which communicate with the housing interior; and whose lower end features a rupture disc, held by 1 disc retainer.
 11. The hydraulic device as claimed in claim 1, wherein the piston located in the annular space between the housing and the cylinder features a diameter that gradually varies along three segments: the first segment, adjusted to the housing; the second segment, slightly smaller and whose length is similar to the lower expansion joints; and the third segment, even smaller than the second one, which goes through the lower sealing means and enters the sliding cone.
 12. The hydraulic device as claimed in claim 1, wherein the lower sealing means comprise: 3 expansion joints, whose position is set by 1 lower joint retainer at the lower segment of the lower piston.
 13. The hydraulic device as claimed in claim 1, wherein the sliding cone is mounted on the lower end of the lower piston and slides between the lower joint retainer and the lower cylinder.
 14. A method for in situ sealing of holes, cracks or leaks in joints, which exist in underground production tubing of oil wells, for the extraction of fluids like oil from the oil wells to the surface, characterized by comprising the following steps: I. displacement of the hydraulic device as claimed in claim
 1. II. location of the hole or crack III. settling of upper section IV. settling of lower section V. completion of the hermetic sealing.
 15. The method for in situ sealing of holes, cracks or leaks in the joints of production tubing as claimed in claim 14, wherein the displacement of the hydraulic device is performed by means of a driving liquid that is pumped from the surface and enters the device through the fishing neck, going through the upper cylinder until it gets pressurized in the rupture disc, thus forcing the hydraulic device to move downwards; through the interior of the production tubing and, at the same time, the fluid outside the hydraulic device causes the expansion of the retainer rubbers, controlling the movement and causing the fluid that is contained in the production tubing below the device to be forced to exit through the leak site on the production tubing, until the detection means or the retainer rubber that is now upside down surpasses the hole or crack, thus bringing the leak to an end.
 16. The method for in situ sealing of holes, cracks or joints in the production tubing as claimed in claim 14, wherein, at the moment when the hole or crack is blocked, the pressure that is measured on the surface is increased up to 8273.76 KPa (1200 psi), which causes the cutting set screws of the hydraulic device to break, thus releasing the upper piston, which begins to go down through the inside of the extension tube at the extension section, and then goes into the interior diameter of the upper expansion joints and presses them against the interior walls of the production tube, leaving the upper section of the hydraulic device hermetically sealed and settled.
 17. The method for in situ sealing of holes, cracks or leaks in the joints of production tubing as claimed in claim 14, wherein, after fixing the upper section of the device, the lower section is then fixed, for which purpose the pressure is increased up to 15,168.56 KPa (2200 psi), which causes the upper rupture disc at the upper section to break; next, the pressure is reduced up to its prior lower value and the pumped fluid flows downwards, through the extension tube at the extension section, in the central cylinder at the central section, and in the lower cylinder at the lower section, and exerts pressure on the lower rupture disc, after which the pressure of the fluid is increased in order to push it through the flow holes in the lower cylinder, until pressure is exerted on the lower piston and a pressure of 9,652.72 KPa (1400 psi) is reached, which causes the 2 lower cutting set screws to break, thus displacing the lower piston downwards, until it goes into the interior diameter of the lower expansion joints and presses them against the interior walls of the production tube, thus leaving the lower section of the hydraulic device hermetically sealed and settled.
 18. The method for in situ sealing of holes, cracks or leaks in joints of the production tubing as claimed in claim 14, wherein, by increasing the pressure used to fix the interior section, the sliding cone is anchored, threaded to the lower piston, in the wedges through the inside of the Cage, thus leaving the lower section of the hydraulic device hermetically sealed and anchored against the walls of the production tubing.
 19. The method for in situ sealing of holes, cracks or leaks in joints of production tubing as claimed in claim 14, wherein, after fixing the upper and lower sections of the hydraulic device for the sealing of holes, cracks or leaks, the settling of the hydraulic device is then verified and once verified, the lower rupture disc breaks, thus establishing communication between the lower, central, and upper cylinders, so that the field fluids may flow normally through the interior of the hydraulic device and the production tubing, in any direction. 